An apparatus including a robot drive, a first arm connected to the robot drive, and a second arm connected to the robot drive. The first arm includes a first upper arm, a first forearm and a first end effector. The second arm includes a second upper arm, a second forearm and a second end effector. The first and second upper arms are connected to a first drive shaft of the robot drive. The first and second upper arms are either a same member or two members stationarily connected to one another. While the first arm is being extended and retracted, straight movement of the first end effector is provided relative to the robot drive along an axis which intersects a drive axis of the robot drive, where a wrist joint of the first arm does not intersect the drive axis while the first arm is being extended and retracted.

An apparatus including a drive having motors and at least two coaxial drive shafts; an arm connected to the drive, where the arm is configured to support at least one substrate thereon; and a transmission connected between the drive and the arm, where the transmission includes an eccentric bearing and a linkage, where the linkage is connected between a first one of the coaxial drive shafts and the arm, where the eccentric bearing is connected to a second one of the coaxial drive shafts, where the arm comprises an aperture, where the eccentric bearing is located in the aperture, and where the eccentric bearing is configured to contact the arm in the aperture.

A transport apparatus including a drive; a first arm connected to the drive, where the first arm includes a first link, a second link and an end effector connected in series with the drive, where the first link and the second link have different effective lengths; and a system for limiting rotation of the end effector relative to the second link to provide substantially only straight movement of the end effector relative to the drive when the first arm is extended or retracted.

An apparatus includes a first arm comprising an unequal-link linkage having a first end effector; a second arm comprising an equal-link linkage having a second end effector; and a drive unit coupled to the first arm and the second arm, the drive unit being configured to move the first arm and the second arm. The first end effector is asymmetric to the second end effector. The first end effector is angled relative to the second end effector such that a first substrate support section on the first end effector is not positioned over or under a second substrate support section on the second end effector.

Disclosed is a surface treatment device. The surface treatment device includes: a frame; a disc hanger; two support wheels for supporting the disk hanger; a rotation drive mechanism for driving the disk hanger supported on the two support wheels to rotate; a vertical spray rack for spraying liquid medicine on the circuit board on the disk hanger; and a lift mechanism for driving the vertical spray rack up and down.

Disclosed is a robot including a variable length unit coupled to one section of at least one arm unit, wherein the variable length unit may include a motor, a first cam having at least one slit having a specific inclination in one area thereof, and a second cam, at least a portion of which is disposed in an interior of the first cam, and having at least one first boss that passes through the at least one slit of the first cam, wherein the first cam may be rotated through driving of the motor, the second cam may be linearly moved while the at least one first boss is guided by the at least one slit in correspondence to rotation of the first cam, and a length of the at least one arm unit may vary in correspondence to linear motion of the second cam.

The invention provides an automated displacement and turnover system and a device thereof. The device comprises a base, a stroke control mechanism disposed on the base, a fixture mounting seat, and a processing fixture assembled on the fixture mounting seat; the stroke control mechanism is in driving connection with the fixture mounting seat, so that the processing fixture is driven by the stroke control mechanism to perform cyclic actions of fixed-point processing at a processing position, linear displacement to a turnover position, fixed-point turning at the turnover position, and linear displacement to the processing position until a processing procedure is completed and an object of automated turnover and processing is realized. In addition, the device is used with a terminal device and a mobile terminal to form an automated displacement and turnover system.

An apparatus includes a first arm comprising an unequal-link linkage having a first end effector; a second arm comprising an equal-link linkage having a second end effector; and a drive unit coupled to the first arm and the second arm, the drive unit being configured to move the first arm and the second arm. The first end effector is asymmetric to the second end effector. The first end effector is angled relative to the second end effector such that a first substrate support section on the first end effector is not positioned over or under a second substrate support section on the second end effector.

An apparatus including a drive having motors and coaxial drive shafts; an arm assembly having a first arm and a second arm; and a controller. The first arm includes a first upper arm, a first forearm, a first end effector, and a first transmission, where the first transmission includes a non-circular pulley, and where the first upper arm and the first forearm have unequal effective lengths. The second arm includes a second upper arm, a second forearm, a second end effector, and a second transmission, where the second upper arm and the second forearm have substantially equal effective lengths. The controller is configured to cause the drive to extend and retract the arms to move an upper substrate and a lower substrate on the substrate holding areas such that the arm assembly and upper substrate do not travel over the lower substrate.

A transport apparatus including a drive with a drive axis and a first arm connected to the drive. The first arm includes a first link, a second link and an end effector connected in series with the drive. The end effector includes a substrate support section and a leg connecting the substrate support section to a wrist joint of the end effector with the second link. The leg has a first section connected to the wrist joint, a second section connected to the substrate support section, and a bend portion between the first and second sections such that the first and second sections are angled or offset relative to each other. Connection of the leg to the second link at the wrist joint is offset relative to a centerline of the substrate support section and offset relative to the drive axis.